CN105453012A

CN105453012A - Cursor location control device, cursor location control method, program, and information storage medium

Info

Publication number: CN105453012A
Application number: CN201480044637.9A
Authority: CN
Inventors: 高瀬昌毅; 直井纯一
Original assignee: Sony Computer Entertainment Inc
Current assignee: Sony Interactive Entertainment Inc
Priority date: 2013-08-20
Filing date: 2014-08-20
Publication date: 2016-03-30
Anticipated expiration: 2034-08-20
Also published as: EP3037941A1; EP3037941B1; JP6049885B2; US10216288B2; WO2015025874A1; CN105453012B; EP3037941A4; US20160170501A1; JPWO2015025874A1

Abstract

An objective of the present invention is to improve manipulability in carrying out a manipulation of moving a cursor to a target location with a controller which outputs manipulation quantity data which is associated with a manipulation quantity vector which represents a manipulated direction and size. A manipulation quantity component specification unit (46) specifies the size of a first manipulation quantity component and the size of a second manipulation quantity component on the basis of manipulation quantity data. A movement quantity component determination unit (48) determines the size of a first movement quantity component and the size of a second movement quantity component. A cursor location change unit (50) changes the location of a cursor to a location removed from the present location of the cursor by the size of the first movement quantity component in a first positioning direction and by the size of the second movement quantity in a second positioning direction. The positioning spacing of options in the second positioning direction is narrower than the positioning spacing of options in the first positioning direction, and the ratio of the size of the second movement quantity component to the size of the second manipulation quantity component is smaller than the ratio of the size of the first movement quantity component to the size of the first manipulation quantity component.

Description

Cursor location control device, cursor position control method, program and information storage medium

Technical field

The present invention relates to cursor location control device, cursor position control method, program and information storage medium.

Background technology

A kind of technology is available, wherein, if then user operation controller performs predetermined determination operation with mobile cursor, then performs the process of the selection corresponding to the position being arranged in cursor.As the example of the technology as just described, the technology of on-screen keyboard is available, wherein when determination operation corresponding to being arranged in the character of image of key of position of cursor as input character processed (such as with reference to PTL1).

A kind of technology is also available, wherein such as represents that the position of the object of the image of target is controlled by controller, and the operational ton data of the operational ton vector association of the direction operated with expression and amplitude export as operation signal by described controller.As such controller as just noted, the controller etc. of output example as the operation signal associated with the tilt quantity of the rotation amount detected by gyro sensor or analog controller is available.In the art, by the direction of operational ton vector representation and the direction of amplitude and object movement and amplitude associated with each other.In the controller exporting the operation signal associated with the rotation amount detected by gyro sensor, if controller such as rotates in the clockwise direction, then object moves right, but if controller rotates in the counterclockwise direction, then object is moved to the left.In addition, such as, when the rotation amount of controller increases, the amount of exercise of object increases.

Reference listing

Patent documentation

PTL1

U.S. Patent Application Pub.No No.2007/0245259

Summary of the invention

Technical matters

Layout distance between the selection of the image of the key in such as on-screen keyboard is such as different between vertical direction and horizontal direction.But in above-mentioned routine techniques, wherein the position of object is controlled by the controller exported with the operational ton data of operational ton vector association, does not consider situation so as above.In other words, the sensitivity (here, the momental amplitude of cursor and the ratio of the amplitude of operational ton) of controller is equal, independent of direction.So, if routine techniques is applied to the operation of the image for moving the cursor to object key, then on direction larger than the layout distance between selecting on the direction that the layout distance between selecting is shorter, more difficult execution is for moving the cursor to the operation of the image of object key.

Make the present invention in view of the above problems, and an object of the present invention is to provide a kind of cursor location control device, a kind of cursor position control method, a kind of program and a kind of information storage medium, thus when the operation for moving the cursor to target location improves operability by when exporting and perform with the controller of the operational ton data of the operational ton vector association in the direction and amplitude that represent operation.

The solution of problem

In order to solve the above problems, according to the present invention, a kind of cursor location control device of the position for controlling the cursor in image is provided, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, it comprises: operational ton data capture unit, and it is configured to obtain the operational ton data with the operational ton vector association representing direction and the amplitude operated; Operational ton component designating unit, it is configured to the amplitude of the amplitude of the first operational ton component of the component of specifying on the basis of operational ton data as the operational ton vector on the first direction of operating and the second operational ton component as the component of the operational ton vector be different from the second direction of operating of the first direction of operating; Amount of exercise component determination unit, it is configured to the amplitude of the first amount of exercise component of the component of the momental amount of exercise vector determined on the basis of the amplitude of the first operational ton component as the described cursor in expression first arranged direction and on the basis of the amplitude of the second operational ton component, determines the amplitude of the second amount of exercise component of the component as the amount of exercise vector in the second arranged direction; And cursor position changes unit, its be configured to by the position of described cursor from the current location of described cursor change into interval first amount of exercise component on the first arranged direction amplitude and in the second arranged direction the position of the amplitude of interval second amount of exercise component, along the second arranged direction selection group between layout distance be shorter than along the first arranged direction between selection group layout distance, the ratio of the amplitude of the second amount of exercise component and the amplitude of the second operational ton component is less than the ratio of the amplitude of the first amount of exercise component and the amplitude of the first operational ton component.

In addition, according to the present invention, a kind of cursor position control method of the position for controlling the cursor in image is provided, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, described method comprises: operational ton data acquisition step, and it obtains the operational ton data with the operational ton vector association representing direction and the amplitude operated; Operational ton component given step, it specifies the amplitude of the amplitude of the first operational ton component of the component as the operational ton vector on the first direction of operating and the second operational ton component as the component of the operational ton vector be different from the second direction of operating of the first direction of operating on the basis of operational ton data; Amount of exercise component determining step, it determines the amplitude of the first amount of exercise component of the component of the momental amount of exercise vector as the described cursor in expression first arranged direction and on the basis of the amplitude of the second operational ton component, determines the amplitude of the second amount of exercise component of the component as the amount of exercise vector in the second arranged direction on the basis of the amplitude of the first operational ton component; And cursor position changes step, its by the position of described cursor from the current location of described cursor change into interval first amount of exercise component on the first arranged direction amplitude and in the second arranged direction the position of the amplitude of interval second amount of exercise component, along the second arranged direction selection group between layout distance be shorter than along the first arranged direction between selection group layout distance, the ratio of the amplitude of the second amount of exercise component and the amplitude of the second operational ton component is less than the ratio of the amplitude of the first amount of exercise component and the amplitude of the first operational ton component.

In addition, according to the present invention, a kind of program performed by computing machine is provided, described computer controlled imaged in the position of cursor, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, and described program causes described computing machine to perform: for obtaining the process with the operational ton data of the operational ton vector association in the direction and amplitude that represent operation; The process of the amplitude of the first operational ton component of the component as the operational ton vector on the first direction of operating and the amplitude as the second operational ton component of the component of the operational ton vector be different from the second direction of operating of the first direction of operating is specified on the basis in operational ton data; On the basis of the amplitude at the first operational ton component, determine the amplitude of the first amount of exercise component of the component of the momental amount of exercise vector as the described cursor in expression first arranged direction and on the basis of the amplitude of the second operational ton component, determine the process of the amplitude of the second amount of exercise component of the component as the amount of exercise vector in the second arranged direction; And for by the position of described cursor from the current location of described cursor change into interval first amount of exercise component on the first arranged direction amplitude and in the second arranged direction the process of the position of the amplitude of interval second amount of exercise component, along the second arranged direction selection group between layout distance be shorter than along the first arranged direction between selection group layout distance, the ratio of the amplitude of the second amount of exercise component and the amplitude of the second operational ton component is less than the ratio of the amplitude of the first amount of exercise component and the amplitude of the first operational ton component.

In addition, according to the present invention, the computer-readable information storage medium of the program providing a kind of storage to be performed by computing machine, described computer controlled imaged in the position of cursor, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, and described program causes described computing machine to perform: for obtaining the process with the operational ton data of the operational ton vector association in the direction and amplitude that represent operation; The process of the amplitude of the first operational ton component of the component as the operational ton vector on the first direction of operating and the amplitude as the second operational ton component of the component of the operational ton vector be different from the second direction of operating of the first direction of operating is specified on the basis in operational ton data; On the basis of the amplitude at the first operational ton component, determine the amplitude of the first amount of exercise component of the component of the momental amount of exercise vector as the described cursor in expression first arranged direction and on the basis of the amplitude of the second operational ton component, determine the process of the amplitude of the second amount of exercise component of the component as the amount of exercise vector in the second arranged direction; And for by the position of described cursor from the current location of described cursor change into interval first amount of exercise component on the first arranged direction amplitude and in the second arranged direction the process of the position of the amplitude of interval second amount of exercise component, along the second arranged direction selection group between layout distance be shorter than along the first arranged direction between selection group layout distance, the ratio of the amplitude of the second amount of exercise component and the amplitude of the second operational ton component is less than the ratio of the amplitude of the first amount of exercise component and the amplitude of the first operational ton component.

In the present invention, the momental amplitude of cursor on the direction that the layout distance between selecting is shorter and the ratio of the amplitude of operational ton are less than is arranging the ratio on the direction that distance is longer.Therefore, using the present invention, when the controller of the operational ton data by using the operational ton vector association exporting and represent its direction operated and amplitude performs the operation for moving the cursor to target location, improving operability.

In an embodiment of the present invention, the first arranged direction is the horizontal direction on described image display display unit thereon, and the second arranged direction is the vertical direction on described display unit.

In addition, in another embodiment of the invention, the position of the described cursor in described image is limited to the region of the part occupying described image.

In this embodiment, described choice arrangement is in the end in described region.

In another embodiment of the invention, described operational ton data capture unit obtains the operational ton data with the rotation amount vector association detected by gyro sensor, described operational ton component designating unit specifies the amplitude of the amplitude of the first rotation amount component of the component as the operational ton vector in the first sense of rotation and the second rotation amount component as the component of the operational ton vector be different from the second sense of rotation of the first sense of rotation on the basis of operational ton data, and described amount of exercise component determination unit is determined the amplitude of the first amount of exercise component and determine the amplitude of the second amount of exercise component on the basis of the amplitude of the second rotation amount component on the basis of the amplitude of the first rotation amount component.

In another embodiment of the present invention, the quantity along the selection of the second arranged direction layout is less than the quantity of the selection of arranging along the first arranged direction.

Accompanying drawing explanation

Fig. 1 is the view of the example of the general configuration that information handling system is according to an embodiment of the invention shown.

Fig. 2 is the view of the example of the hardware configuration that signal conditioning package is according to an embodiment of the invention shown.

Fig. 3 is the view of the example of the outward appearance that controller is according to an embodiment of the invention shown.

Fig. 4 is the view of the example that whole image is shown.

Fig. 5 is the view of another example that whole image is shown.

Fig. 6 is the view of example key being shown and determining the relation between region.

Fig. 7 is the view of the example that testing result space is shown.

Fig. 8 is the view of the example of the relation illustrated between operation coordinate figure and operational ton component value.

Fig. 9 is the view of the example that cursor space is shown.

Figure 10 is the view of the example of the relation illustrated between the position of cursor and moving area.

Figure 11 is the view of the example of the relation illustrated between the absolute value of operational ton component value and the absolute value of amount of exercise component value.

Figure 12 is the view of the example of the relation illustrated between cursor coordinates value and amount of exercise component value.

Figure 13 is the view of the example of the mode that moving area movement is shown.

Figure 14 is the view of another example that whole image is shown.

Figure 15 is the functional block diagram of the example that the function comprised in signal conditioning package is according to an embodiment of the invention shown.

Figure 16 illustrates the process flow diagram by the example of the flow process of the process of signal conditioning package execution according to an embodiment of the invention.

Embodiment

Below, embodiments of the invention are described in detail with reference to accompanying drawing.

Fig. 1 is the view of the example of the general configuration that information handling system 10 is according to an embodiment of the invention shown.As shown in fig. 1, signal conditioning package 12, controller 14 and display unit 16 is comprised according to the information handling system 10 of the present embodiment.

Be such as computing machine according to the signal conditioning package 12 of the present embodiment, as game device or personal computer, and as shown in Figure 2, such as, comprise control module 20, storage unit 22 and communication unit 24.Control module 20 is such as the program control facility according to being arranged on the procedure operation in signal conditioning package 12, as CPU.Storage unit 22 is such as memory element, as ROM or RAM, hard disk drive etc.The program performed by control module 20 is stored in storage unit 22.Communication unit 24 is such as communication interface, as network board or wireless LAN module.

According to the input device that the controller 14 of the present embodiment is for performing the operation being input to signal conditioning package 12.Fig. 3 is the view of the example of the outward appearance of the controller 14 illustrated according to the present embodiment.In the present embodiment, on controller 14, arrange four direction key DK1 to DK4, four button B1 to B4, and two analog controller AC1 and AC2.Controller 14 also comprises other functional unit.In addition, the controller 14 according to the present embodiment comprises sensor, as the gyro sensor of detection angle speed and the acceleration transducer of sense acceleration.It should be noted that the electronic compass (geomagnetic sensor) that can comprise detection orientation according to the controller 14 of the present embodiment.In addition, comprise network board, wireless LAN module etc. according to the controller 14 of the present embodiment and can be communicated with signal conditioning package 12 by wire communication or radio communication.In the description provided below, suppose that the Y1 direction shown in Fig. 3 and Y2 direction are forward direction and backward directions respectively.In addition, suppose that X1 direction and X2 direction are right direction and left direction respectively.In addition, suppose that Z1 direction and Z2 direction are upward direction and in downward direction respectively.

Liquid crystal display, organic EL display unit etc. according to the display unit 16 of the present embodiment.In the present embodiment, signal conditioning package 12 and display unit 16 are connected to each other by the cable of such as HDMI (registered trademark) (HDMI (High Definition Multimedia Interface)) cable or USB (USB (universal serial bus)) cable.

Fig. 4 is the view of the example of the image that display on the display unit 16 in the present embodiment is shown.In the following description, image is called as whole image 30.In the present embodiment, the region occupying a part for whole image 30 is set to the image layout on-screen keyboard region 32 wherein of on-screen keyboard.

On-screen keyboard region 32 comprises character string layout area 32a, predicting candidate layout area 32b and key layout area 32c.Character string is arranged in character string layout area 32a in the present embodiment.In addition, in predicting candidate layout area 32b in the present embodiment, the list of one or more predicting candidate that the basis being arranged in the character string in character string layout area 32a is specified is arranged under horizontal apposition.In addition, in key layout area 32c, multiple selection is arranged, such as, in the present embodiment, the image of multiple key K.

In the present embodiment, key K with matrix arrangements in key layout area 32c.Especially, in key layout area 32c, each multiple key group in the vertical directions of multiple key K of arranging along horizontal direction of comprising are with arranged in rows.Especially, such as, 10 key K put with four arrangements in the horizontal direction, start from top row.In addition, in the row under four rows, six key K arrange in the horizontal direction, and are descending in row most, and eight key K arrange in the horizontal direction.

In addition, as shown in Figure 4, in the present embodiment, along vertical direction key K between layout distance be shorter than along horizontal direction between key K layout distance.In addition, the quantity of key K of arranging along vertical direction is less than the quantity of the key K arranged along horizontal direction.

Cursor C is also arranged on whole image 30.Cursor C in the present embodiment is circular diagram.In the present embodiment, user can move cursor C by operation control 14.In the present embodiment, the change of the attitude of the position response controller 14 of cursor C, namely responds the rotation amount of the controller 14 detected by the gyro sensor provided in controller 14 and changes.In the present embodiment, such as, if user performs the axis rotation process in the counterclockwise direction provided around the X1-X2 direction by controller 14 when observing along X2 direction, then cursor C moves in an upward direction, if but user performs rotation process in the clockwise direction, then cursor C moves in a downward direction.In addition, if user performs the axis rotation process in the counterclockwise direction provided around the Z1-Z2 direction by controller 14 when observing along Z2 direction, then cursor C is moving up to the left, if but user performs rotation process in the clockwise direction, then cursor C is moving up to the right.

In the present embodiment, one in multiple key K is defined as key K under selected state on the basis of the position of cursor C, then highlights the key K under selected state.In the diagram, represent around the rectangle of the key K as the target highlighted and highlight relative keys K.In on-screen keyboard in the diagram, the key K corresponding to character " f " is in selected state.

If user performs determination operation, such as, in the present embodiment, the operation of push button B1, then operation is regarded as making inputting the key K under selected state, and the character corresponding to relative keys K is joined the character string be arranged in character string layout area 32a.Fig. 5 illustrates when cursor C is from the whole image 30 of whole the image 30 and state then performing determination operation moves up left during cursor C shown in display Fig. 4.In on-screen keyboard in Figure 5, the key K corresponding to character " e " is in selected state, and character " e " joins the character string be arranged in character string layout area 32a.

Then, if the enter key EK at the bottom-right location place being arranged in key layout area 32c is placed in selected state and then performs determination operation by user, then the character string be arranged in character string layout area 32a is regarded as the input of character string of signal conditioning package 12.Then, the process corresponding to character string is performed.

In the present embodiment, if the key K under selected state exists as shown in Figure 6, then when the position of the center of gravity G of cursor C moves in the decision region DA of the part occupying key K, the key K under selected state is updated to relative keys K.In the present embodiment, the decision region DA occupying a part of key K has center of gravity, and the position of described center of gravity overlaps with the center of gravity of relative keys K.In addition, in the present embodiment, the height of decision region DA and width equal the height of key K and the prearranged multiple of width, and such as 7/8.In like fashion, in the present embodiment, when the border of cursor C adjacent keys K is arranged, prevent the key K under selected state from upgrading to cross high-frequency.

In addition, in the present embodiment, the operation for being moved to by cursor C in character string layout area 32a or predicting candidate layout area 32b can be performed.And, the operation of the scope for indicating the character be arranged in character string layout area 32a can be performed, for cancelling another operation of sign scope, with for the another operation of the predicting candidate of choice arrangement in predicting candidate layout area 32b.Here, when the position of the center of gravity G of cursor C is placed in character string layout area 32a, button cursor C can erase from whole image 30 and indicate another cursor of the vertical bar shape of the additional position of the character be arranged in character string layout area 32a (insertion symbol) to glimmer.In addition, at this moment, as the replacement or additional of the flicker of insertion symbol, the color inserting symbol can change.This makes it possible to allow user recognize can operation in execution character string layout area 32a.In addition, when the position of the center of gravity G of cursor C departs from character string layout area 32a or depart from the presumptive area around character string layout area 32a, button cursor C can be arranged in whole image 30 again.

Below, the mobile operation of the cursor C in the present embodiment is further described.Fig. 7 illustrates the example in testing result space 34, and it is the virtual three-dimensional space of the relation represented between the attitude of controller 14 and the parameter representing attitude.In testing result space 34 in the figure 7, suppose in the direction of this side it is X-axis positive dirction; Upward direction is Y-axis positive dirction; And right direction is Z axis positive dirction.Z axis positive dirction is called as reference direction.

In the present embodiment, the basis of the rotation information of the hypercomplex number form of the result as the detection produced by gyro sensor is specified the attitude relative to reference direction.In the present embodiment, in an initial condition maybe when performing replacement operation, the Y1 direction of controller 14 is set to consistent with the reference direction in the testing result space 34 shown in Fig. 7.It should be noted that in the present embodiment, the depression of analog controller AC1 is regarded as replacement operation.Then, the basis of the rotation information of the attitude description above with reference to the controller 14 under original state maybe when performing replacement operation is specified the attitude of the controller 14 relative to reference direction.In the present embodiment, represented by the coordinate figure (λ o, θ o) in the spheric coordinate system arranged in testing result space 34 shown in the figure 7 relative to the attitude of reference direction.Coordinate figure is hereinafter referred to as operation coordinate figure.In the present embodiment, value λ o represents that in the direction from Z axis positive dirction to the rotation of X-axis positive dirction be positive angle.Value θ o represents from being positive angle along the direction of XZ plane towards the direction of the rotation of Y-axis positive dirction.In addition, in the present embodiment, when observing along Z2 direction, around Z1-Z2 direction, the rotation of controller 14 is in the clockwise direction regarded as the rotation of added value λ o, and rotation is in the counterclockwise direction regarded as the rotation of decreasing value λ o.In addition, in the present embodiment, when observing along X2 direction, around X1-X2 direction, the rotation of controller 14 is in the counterclockwise direction regarded as the rotation of added value θ o, and rotation is in the clockwise direction regarded as the rotation of decreasing value θ o.

In the present embodiment, perform by gyro sensor test pose with predetermined frame rate.In the present embodiment, after each interval of such as 1/60 second, perform the detection of attitude.In addition, with the appointment of predetermined frame rate executable operations coordinate figure (λ o, θ o).In addition, in the present embodiment, the basis of the operational ton (such as, in the present embodiment, the rotation amount of the controller 14 in a frame) in the frame detected is determined the amount of exercise of cursor C, that is, the variable quantity of the position of cursor C.In the following description, operation coordinate figure (λ o in a frame, θ o) the difference of λ o component be called as the first operational ton component, and the difference of the θ o component of operation coordinate figure (λ o, θ o) in a frame is called as the first operational ton component.In addition, the value of the first operational ton component is expressed as the first operational ton component value Δ λ o, and the value of the second operational ton component is expressed as the second operational ton component value Δ θ o.

Such as, suppose to specify the operation coordinate figure (λ o, θ o) in certain frame to be (λ o1, θ o1).Then, suppose to specify the operation coordinate figure (λ o, θ o) in next frame to be (λ o2, θ o2).In this case, the first operational ton component value Δ λ o is provided by λ o2-λ o1, and the second operational ton component value Δ θ o is provided by θ o2-θ o1.

In addition, in the present embodiment, the amount of exercise of the cursor C in a frame in the spheric coordinate system arranged in the cursor space 36 shown in the basis of the first operational ton component value Δ λ o and the second operational ton component value Δ θ o being determined in fig .9.

Fig. 9 illustrates the example in the cursor space 36 as virtual three-dimensional space, wherein display highlighting C position and occupy on-screen keyboard a part moving area MA (with reference to Figure 10) between relation.On sphere in cursor space 36 in fig .9, arrange cursor C and moving area MA.In cursor space 36 in fig .9, the direction towards this side is X-axis positive dirction; Upward direction is Y-axis positive dirction; And right direction is Z axis positive dirction.Z axis positive dirction is called as reference direction.

In the present embodiment, if determine the amount of exercise of cursor C, then on momental basis, determine the position of cursor C in the spheric coordinate system in the cursor space 36 shown in Fig. 9 and moving area MA.Then here, suppose that the position of center of gravity of cursor C in the spheric coordinate system arranged in the cursor space 36 is in fig .9 represented by coordinate figure (λ c, θ c).In fig .9, coordinate figure is illustrated by G (λ c, θ c).Coordinate figure is hereinafter referred to as cursor coordinates value.In addition, the positional representation in four bights of moving area MA is (λ 1, θ 1), (λ 1, θ 2), (λ 2, θ 1) and (λ 2, θ 2).It should be noted that value λ 1 is less than value λ 2 and is worth θ 1 and be less than value θ 2.In the present embodiment, value λ c, λ 1 and λ 2 represent rotation angle, just be wherein from Z axis positive dirction towards the direction of the rotation of X-axis positive dirction, and be worth θ c, θ 1 and θ 2 and represent rotation angle, wherein from being just along the direction of XZ plane towards the direction of the rotation of Y-axis positive dirction.

Figure 10 illustrates the example of the position relationship between on-screen keyboard and moving area MA.In Fig. 10, the character be arranged on key K is omitted.Be transformed into from portion of spherical coordinate region that plane obtains by the moving area MA shown in Fig. 9 and be designated as moving area MA Figure 10.Especially, with the coordinate figure (λ 1 in Fig. 9, θ 1), (λ 1, θ 2), (λ 2, θ 1) and (λ 2, θ 2) position of associating is coordinate figure (x1 in Figure 10, y1), (x1, y2), the position of (x2, y1) and (x2, y2).In addition, in the present embodiment, the relative position of the cursor C when the moving area MA shown in Fig. 9 is transformed into plane from portion of spherical coordinate moving area MA also in Fig. 10 shown in moving area MA in keep.In the present embodiment, cursor C the scope of movement wherein can be limited to moving area MA.

In the following description, cursor coordinates value (λ c in a frame, θ c) λ c component between difference be expressed as the first amount of exercise component, and the difference between the θ c component of cursor coordinates value (λ c, θ c) in a frame is expressed as the second amount of exercise component.In addition, the value of the first amount of exercise component is expressed as the first amount of exercise component value Δ θ c, and the value of the second amount of exercise component is expressed as the second amount of exercise component value Δ θ c.In the present embodiment, the first amount of exercise component value Δ λ c is determined on the basis tying up to the first operational ton component value Δ λ o according to the pass shown in Figure 11 and on the basis of the second operational ton component value Δ θ o, determines the second amount of exercise component value Δ θ c.Figure 11 illustrates the example of the relation between the absolute value of relation between the absolute value of the first operational ton component value Δ λ o and the absolute value of the first amount of exercise component value Δ λ c and the second operational ton component value Δ θ o and the absolute value of the second amount of exercise component value Δ θ c.It should be noted that the symbol of the symbol of the first operational ton component value Δ λ o and the first amount of exercise component value Δ λ c is consistent with each other, and the symbol of the symbol of the second operational ton component value Δ θ o and the second amount of exercise component value Δ θ c is consistent with each other.In addition, the current location of the center of gravity G of cursor C and the basis of the first amount of exercise component value Δ λ c and the second amount of exercise component value Δ θ c are determined the cursor coordinates value (λ c, θ c) after the motion of the cursor C in frame.Such as, the cursor coordinates value (λ c, θ c) supposing the position of the center of gravity G of the cursor C represented in certain frame is (λ c1, θ c1).In addition, suppose to determine the first amount of exercise component value Δ λ c and the second amount of exercise component value Δ θ c.In this case, if the cursor coordinates value (λ c, θ c) representing the position of the center of gravity G of cursor C after the motion of the cursor C in frame is (λ c2, θ c2), then value λ c2 becomes λ c1+ Δ λ c, and is worth θ c2 and becomes θ c1+ Δ θ c.

Below, the relation shown in Figure 11 is further described.In the present embodiment, be expressed as low-speed range R1 in fig. 11 and in the scope that wherein absolute value of operational ton component value is low, the relation between the absolute value of operational ton component value and the absolute value of amount of exercise component value associated with operational ton component is represented by exponential function.So absolute value and the ratio of the absolute value of operational ton component value of the amount of exercise component value associated with operational ton component are less than the ratio under the alternative case increased with being proportional to one another at the absolute value of operational ton component value and the absolute value of amount of exercise component value that associates with operational ton component.That is, the sensitivity sensitivity of controller 14 increases lower than the absolute value at operational ton component value and the absolute value of amount of exercise component value that associates with operational ton component with being proportional to one another.So, in the present embodiment, but can suppress when in fact controller 14 swings the motion of the less desirable cursor C of user occurred when user guesses that controller 14 stops.In addition, in the present embodiment, because the sensitivity of controller 14 is low in low-speed range R1, therefore user can perform the location of cursor C with pinpoint accuracy.So, in the present embodiment, easily can perform and cursor C is navigated to target location.Same in low-speed range R1, if the absolute value of operational ton component value is not 0, then the absolute value of the amount of exercise component value associated with operational ton component is not 0.So when the operation of controller 14 just being detected, cursor C moves, and therefore, user can recognize just in the operation of implementation controller 14.

In addition, in the present embodiment, in the scope except low-speed range R1, the absolute value of operational ton component value and the absolute value of amount of exercise component value associated with operational ton component increase with being proportional to one another.In addition, in the region that the absolute value of operational ton component value is high, the ratio of the absolute value of the amount of exercise component value associated with operational ton component and the absolute value of operational ton component value is the ratio in medium another region higher than the absolute value at operational ton component value.The scope that the absolute value of operational ton component value is high is expressed as high-speed range R3 in fig. 11, and the absolute value of operational ton component value is medium scope is expressed as moderate speed range R2 in fig. 11.By above-mentioned configuration, in high-speed range R3, the ratio of the momental value representing cursor C and the value representing operational ton is higher than the ratio in moderate speed range R2, and therefore, the operational ton when cursor C moves fast reduces.

In addition, in the present embodiment, the ratio of the absolute value of the second amount of exercise component value Δ θ c and the absolute value of the second operational ton component value Δ θ o is less than the ratio of the absolute value of the first amount of exercise component value Δ λ c and the absolute value of the first operational ton component value Δ λ o.Especially, such as, when the absolute value of the second operational ton component value Δ θ o is 1.5 times of the absolute value of the first operational ton component value Δ λ o, the absolute value of the first amount of exercise component value Δ λ c and the absolute value of the second amount of exercise component value Δ θ c are equal to each other.Figure 11 illustrates that the absolute value of the first operational ton component value Δ λ o equals b and the absolute value of the second operational ton component value Δ θ o is 1.5b when the absolute value of the first amount of exercise component value Δ λ c and the absolute value of the second amount of exercise component value Δ θ c equal a.In other words, the sensitivity in the vertical direction of controller 14 is lower than in the horizontal direction.In the present embodiment, due to the layout distance between the key K that the layout distance between the key K along vertical direction is shorter than along horizontal direction, therefore vertical direction needs meticulousr operation than horizontal direction.In addition, the quantity due to the key K arranged along vertical direction is less than the quantity of the key K arranged along horizontal direction, therefore when being tended to become large in the horizontal direction by the amount of exercise of cursor C during options button K.Meanwhile, in the vertical direction, the position of cursor C is tended to by the operation of functional unit (as directionkeys DK1 to DK4 or button B1 to B4) fuzzy.In the present embodiment, consider afore-mentioned, the sensitivity of the controller 14 of in the vertical direction is set to sensitivity lower than controller 14 in the horizontal direction to improve the operability of the operation for cursor C being moved to target location.

In addition, in the present embodiment, performing in the predetermined a period of time (such as, five frames, that is, about 80 milliseconds) after determination operation, the motion of cursor C is suppressed.So, in the present embodiment, suppress the motion of the less desirable cursor C of user such as, produced by determination operation (in the present embodiment, button B1 press down).

In addition, in the present embodiment, if the position of the center of gravity G of cursor C is outside the scope of moving area MA after movement, then moving area MA moves along the direction of moving of cursor C, and maintenance cursor C is arranged in the state in moving area MA thus.Therefore, the mobile range of cursor C is limited to moving area MA in like fashion.Such as, to left movement from (λ c', θ c') the changing into of position (λ c ", θ c') of the cursor coordinates value (λ c, θ c) of the position representing center of gravity G due to the center of gravity G of cursor C is supposed, as shown in Figure 13.In addition, suppose that the position of the center of gravity G of cursor C after movement exceeds the scope of moving area MA.In this case, moving area MA is moving up to the left along the sphere in cursor space 36, as shown in Figure 13, makes the position of the center of gravity G of cursor C after movement can in the position in the left side of moving area MA.In other words, moving area MA makes value λ c along the sphere in cursor space 36 moving up to the left " can be set to represent the coordinate figure λ 1 in the position in the left side of moving area MA.Owing to can change the attitude of controller 14 in the present embodiment when the state keeping cursor C to be arranged on the edge of moving area MA in like fashion, therefore, it is possible to adjustment control 14 makes it have a kind of attitude, wherein it easily can be operated by user.Therefore, user must perform such situation minimizing of replacement operation clearly.

In addition, in the present embodiment, moving area MA is the rectangular area of the part occupying on-screen keyboard, and as shown in Figure 10, and key K is arranged in a left side of moving area MA, the position on lower and right side.Especially, enter key EK is arranged in the lower right position of moving area MA.In the present embodiment, because key K is arranged on the edge of moving area MA, therefore when user attempts the key K of choice arrangement on the edge of moving area MA, user can perform for the operation of mobile cursor C and not should be noted that amount of exercise.In like fashion, use the present embodiment, improve the operability by cursor C options button K.In addition, can recognize from description above, it is desirable to the key K very frequently used (such as, enter key EK) to be arranged on the neighboring of on-screen keyboard, that is, on the edge of moving area MA.

In addition, in the present embodiment, in an initial condition maybe when performing replacement operation, the Y1 direction of controller 14 is set to consistent, as noted before with the reference direction in the testing result space 34 shown in Fig. 7.In addition, in the present embodiment, in an initial condition maybe when performing replacement operation, the Y1 direction of controller 14 is also set to consistent with the reference direction in the cursor space 36 shown in Fig. 9.In addition, in the present embodiment, in an initial condition maybe when performing replacement operation, operation coordinate figure (λ o, θ o) and cursor coordinates value (λ c, θ c) are set to (0,0).In addition, in the present embodiment, in an initial condition maybe when performing replacement operation, the position of the moving area MA in cursor space 36 is arranged so that the position of the center of gravity of the moving area MA shown in Fig. 9 overlaps with the position of the center of gravity G of cursor C.

In addition, in the present embodiment, if the angle limited by the direction of the attitude corresponding to controller 14 and reference direction be arranged in the state on the edge of moving area MA at the center of gravity G of cursor C under is more than 45 degree, then performs and force reset process.When the same center of gravity state be arranged on the edge of moving area MA as cursor C continues predetermined a period of time (such as, 8 seconds), perform and force reset process.Force reset process if performed, then the Y1 direction of controller 14 is set to consistent with the reference direction in testing result space 34 and the Y1 direction of controller 14 is set to the reference direction in cursor space 36 consistent.In addition, the position of the moving area MA in cursor space 36 is arranged so that the position keeping the cursor C in the moving area MA shown in Fig. 8 before performing pressure reset process.In addition, in the present embodiment, in the motion performing suppression cursor C in the predetermined a period of time (such as, two frames, that is, about 32 milliseconds) forced after reset process.In gyro sensor, after the detection starting attitude, accumulate the displacement of attitude from benchmark as the time lapses.Therefore, the position of cursor C is sometimes fuzzy or the drift of cursor C also under static state movement occurs sometimes.So, the process when the replacement described in performing operates or above-mentioned pressure reset process at any time must be performed.In the present embodiment, force reset process even if perform, the position of the cursor C in the moving area MA shown in Fig. 8 also keeps, and therefore, can perform and force reset process and do not noted by user.

In addition, in the present embodiment, user can change the position in the on-screen keyboard region 32 in whole image 30.In the present embodiment, if user performs for pressing down the operation of directionkeys DK or the operation for the analog controller AC that tilts, then on-screen keyboard region 32 with press down on direction that directionkeys DK associates or move on the vergence direction of analog controller AC.Figure 14 illustrates the whole image 30 when on-screen keyboard region 32 moves up from the state that the whole image 30 shown in Fig. 5 shows left.In the present embodiment, even if on-screen keyboard region 32 is moved, if the attitude of controller 14 does not change, then the position of the cursor C in moving area MA does not change.

As mentioned above, the cursor location control device of the position controlling cursor C is used as according to the signal conditioning package 12 of the present embodiment.Below, further describing of the moving process of cursor C is mainly provided.

Figure 15 is the functional block diagram of the example that the function comprised in the signal conditioning package 12 according to the present embodiment is shown.It should be noted that and do not need to comprise all functions shown in Figure 15 according to the signal conditioning package 12 of the present embodiment and the one or more functions being different from the function shown in Figure 15 can be comprised.

As shown in Figure 15, signal conditioning package 12 according to the present embodiment such as comprises coordinate data storage unit 40, relation data storage unit 42, operational ton data capture unit 44, operational ton component designating unit 46, amount of exercise component determination unit 48, cursor position changes unit 50, moving area changes unit 52, whole image creation unit 54, and indicative control unit 56.Coordinate data storage unit 40 and relation data storage unit 42 involved mainly as storage unit 22.Operational ton data capture unit 44 is involved mainly as communication unit 24.Other function is involved mainly as control module 20.

Above-mentioned function is comprised by the execution control module 20 be arranged on as the program in the signal conditioning package 12 of computing machine, and program comprises the instruction corresponding to above-mentioned function.This program is such as supplied to signal conditioning package 12 by computer-readable information storage medium (as CD, disk, tape, magneto-optic disk or flash memory) or by computer network (as internet).

Coordinate data storage unit 40 stores the operation coordinate figure data of instruction operation coordinate figure (λ o, θ o) and the cursor coordinates Value Data of instructs cursor coordinate figure (λ c, θ c) in the present embodiment.In addition, coordinate data storage unit 40 stores coordinate figure (λ 1, θ 1), (λ 1, θ 2), (λ 2 of the position in four bights of instruction moving area MA, θ 1) and the moving area coordinate figure data of (λ 2, θ 2).

Relation data storage unit 42 stores the second relation data of the relation between the first relation data of the relation between instruction first operational ton component value Δ λ o and the first amount of exercise component value Δ λ c and instruction the second operational ton component value Δ θ o and the second amount of exercise component value Δ θ c in the present embodiment.First relation data and the second relation data are such as involved as table operational ton component value and amount of exercise component value associated with operational ton component.It should be noted that the first relation data can be involved as the data of instruction mathematical formulae (as determined the function of the amount of movement component value associated with operational ton component on the basis of operational ton component value) with the second relation data.

Operational ton data capture unit 44 obtains and is transferred to there and the operational ton data of the operational ton vector association of the direction operated with expression and amplitude from controller 14.Operational ton data capture unit 44 obtains the rotation information of the hypercomplex number form such as detected by gyro sensor in the present embodiment as the operational ton data with rotation amount vector association.It should be noted that operational ton data capture unit 44 can obtain the operational ton data associated with the testing result of the sensor of the rotation information be different from detected by gyro sensor.Especially, when analog controller AC tilts, operational ton data capture unit 44 can obtain the operational ton data with the operational ton vector association in the direction and amplitude that represent banking motion.

Operational ton component designating unit 46 specifies the amplitude of the amplitude of the first operational ton component of the component as the operational ton vector on the first direction of operating and the second operational ton component as the component of the operational ton vector be different from the second direction of the first direction of operating.Operational ton component designating unit 46 such as specifies the first operational ton component value Δ λ o and the second operational ton component value Δ θ o in the present embodiment in the operation coordinate figure data be stored in coordinate data storage unit 40 and the basis of operational ton data obtained by operational ton data capture unit 44.Then, operation coordinate figure (the λ o that operational ton component designating unit 46 will be indicated by the operation coordinate figure data be stored in coordinate data storage unit 40, θ o) be updated to the operation coordinate figure (λ o, θ o) of specifying on the basis of operational ton data.

In the present embodiment, the first direction of operating corresponds to the sense of rotation around the Z1-Z2 direction of controller 14, and the second direction of operating corresponds to the sense of rotation around the X1-X2 direction of controller 14.It should be noted that the first direction of operating or second direction are not limited to above-mentioned direction of operating.Such as, the sense of rotation around the controller 14 in Y1-Y2 direction can correspond to the first direction of operating or the second direction of operating.

Amount of exercise component determination unit 48 determines the amplitude of the first amount of movement component as the component in the first arranged direction of the momental amount of movement vector representing cursor C on the basis of the amplitude of the first operational ton component.In addition, amount of exercise component determination unit 48 determines the amplitude of the second amount of movement component as the component in the second arranged direction of amount of movement vector on the basis of the amplitude of the second operational ton component.

Here, the first arranged direction or the second arranged direction represent the arranged direction of selection.In addition, along the second arranged direction selection between layout distance be shorter than along the first arranged direction between selection layout distance.It should be noted that the quantity of the selection of arranging along the second arranged direction can be less than the quantity of the selection of arranging along the first arranged direction.In the present embodiment, along vertical direction key K between layout distance be shorter than along horizontal direction between key K layout distance, as noted before.In addition, the quantity of key K of arranging along vertical direction is less than the quantity of the key K arranged along horizontal direction.So in the present embodiment, the first arranged direction corresponds to horizontal direction and the second arranged direction corresponds to vertical direction.It should be noted that the first arranged direction or the second arranged direction need not be horizontal direction or vertical direction.

In addition, in the present embodiment, the ratio of the amplitude of the first amount of movement component and the amplitude of the first operational ton component is less than the ratio of the amplitude of the second amount of movement component and the amplitude of the second operational ton component.

In the present embodiment, amount of exercise component determination unit 48 such as determines the first amount of exercise component value Δ λ c especially on the basis of the first relation data and the first operational ton component value Δ λ o.In addition, amount of exercise component determination unit 48 such as determines the second amount of exercise component value Δ θ c especially on the basis of the second relation data and the second operational ton component value Δ θ o.

Cursor position change unit 50 by the position of cursor C from the current location of cursor C change into interval first amount of movement component on the first arranged direction amplitude and in the second arranged direction the position of the amplitude of interval second amount of movement component.Cursor position changes unit 50 and obtains the cursor coordinates value (λ c, θ c) such as indicated by the cursor coordinates Value Data be stored in coordinate data storage unit 40 in the present embodiment.Then, cursor position changes unit 50 at cursor coordinates value (λ c, θ c) and the first amount of exercise component value Δ λ c and the second amount of exercise component value Δ θ c basis on specify the coordinate figure (λ c, θ c) of position of the cursor C after instruction motion.Then, the cursor coordinates value (λ c, θ c) indicated by the cursor coordinates Value Data be stored in coordinate data storage unit 40 is updated to and specifies cursor coordinates value (λ c, θ c) by cursor position change unit 50.

If the position of the center of gravity G of the cursor C after motion is outside moving area MA, then moving area change unit 52 moves moving area MA in mode so as above.More particularly, such as, if cursor coordinates value (the λ c after motion, θ c) four coordinate figures indicated by moving area coordinate figure data to around region outside, then moving area change unit 52 with mode so as above upgrade by moving area coordinate figure data indicate four coordinate figures pair.

Whole image creation unit 54 creates whole image 30 on the basis of the cursor coordinates Value Data be stored in coordinate data storage unit 40 and moving area coordinate figure data.

The whole image 30 created by whole image creation unit 54 is outputted to display unit 16 by indicative control unit 56.

Here, describe by the example of the flow process of the process performed for each frame according to the signal conditioning package 12 of the present embodiment with reference to the process flow diagram shown in Figure 16.

First, operational ton data capture unit 44 obtains the operational ton data (S101) associated with the testing result that gyro sensor produces.Then, operational ton data capture unit 44 specifies the operation coordinate figure (λ o, θ o) (S102) in associated frame on the basis of the operational ton data of the Procedure Acquisition indicated by S101.Then, operation coordinate figure (the λ o that operational ton data capture unit 44 is specified in the process indicated by S102, θ o) and the operation coordinate figure (λ o, θ o) being stored in coordinate data storage unit 40 between difference basis on appointment first operational ton component value Δ λ o and the second operational ton component value Δ θ o (S103).Then, operation coordinate figure (the λ o that operational ton component designating unit 46 will be indicated by the operation coordinate figure be stored in coordinate data storage unit 40, θ o) be updated to the operation coordinate figure (λ o, θ o) (S104) of being specified by the process of S102 instruction.

Then, amount of exercise component determination unit 48 determines whether to meet predetermined rejection condition (S105).Here, if meet the predetermined period of such as current time after execution determination operation (such as, five frames) in or current time performing the condition in the predetermined period (such as, two frames) forced after reset process, then determine to meet predetermined rejection condition.

If determine not meet predetermined rejection condition (S105: no), then amount of exercise component determination unit 48 determines the first amount of exercise component value Δ λ c (S016) on the basis of the first operational ton component value Δ λ o that the first relation data and the process that indicated by S103 are specified.Then, amount of exercise component determination unit 48 determines the second amount of exercise component value Δ θ o (S017) on the basis of the second operational ton component value Δ θ o that the second relation data and the process that indicated by S103 are specified.

Then, cursor position change unit 50 specifies the cursor coordinates value (λ c, θ c) (S108) after the motion of cursor C.At this moment, in present treatment example, cursor coordinates value (the λ c indicated by cursor coordinates Value Data, θ c) the value of θ c component and the basis of the first amount of exercise component value Δ λ c determined of the process that indicated by S106 on the value of θ c component of cursor coordinates value (λ c, θ c) of cursor C after designated movement.In addition, cursor coordinates value (the λ c indicated by cursor coordinates Value Data, θ c) the value of λ c component and the basis of the second amount of exercise component value Δ θ c determined of the process that indicated by S107 on specify the value of the λ c component of the cursor coordinates value (λ c, θ c) of the position of the cursor C after instruction motion.

Then, cursor position changes cursor coordinates value (the λ c that unit 50 will be indicated by the cursor coordinates Value Data be stored in coordinate data storage unit 40, θ c) be updated to the cursor coordinates value (λ c, θ c) (S109) of being specified by the process of S108 instruction.

Then, moving area changes unit 52 and determines that the position of the center of gravity G of cursor C is whether outside moving area MA (S110).By the process of S110 place instruction, such as determine especially by the position that represents of cursor coordinates value (λ c, θ c) after upgrading four cursor values indicated by moving area coordinate figure data to around region outside.If position is (S110: yes) outside moving area MA, then moving area changes unit 52 mobile moving area MA (S111) as noted before.Especially by the process of S111 place instruction, such as, four coordinate figures pair indicated by the moving area coordinate figure data be stored in coordinate data storage unit 40 are upgraded.

If position in moving area MA (S110: no) if or S111 place instruction process terminate, then whole image creation unit 54 determines the relative position (S112) of the center of gravity G of the cursor C in the moving area MA shown in Figure 10.By the process of S112 place instruction, such as, on the basis of cursor coordinates Value Data and moving area coordinate figure data, determine relative position.

Then, if by S105 indicate process determine to meet predetermined rejection condition (S105: yes) if or S112 place instruction process terminate, then whole image creation unit 54 creates the whole image 30 (S113) comprising moving area MA, and wherein the center of gravity G of cursor C is arranged in the position determined by the process of S112 instruction.

Then, the whole image 30 that the process indicated by S113 creates is outputted to display unit 16 (S114) and then terminates the process that indicates in present treatment example by indicative control unit 56.When display unit 16 receives the whole image 30 of the output of process indicated by S115, it shows whole image 30 on its screen.

It should be noted that the invention is not restricted to the embodiments described.

Such as, on-screen keyboard can have variable-sized.Then, such as, on the basis of the size of on-screen keyboard, the amplitude of the amount of exercise component associated with operational ton component relative to the amplitude of operational ton component can be determined.More particularly, such as, when the size of on-screen keyboard reduces, the amplitude of the amount of exercise component associated with operational ton component relative to the amplitude of operational ton component can reduce.

Alternatively, user can change the amplitude of the amount of exercise component associated with operational ton component relative to the amplitude of operational ton component.

Alternatively, signal conditioning package 12 can have the display unit 16 be configured in wherein.Alternatively, signal conditioning package 12 can configure from multiple shell.In addition, the specific character string in the specific character string above indicated or figure is exemplary, and does not limit such character string.

Claims (amendment according to treaty the 19th article)

1. a cursor location control device, for control for from multiple selection to select the cursor of in described multiple selection will the position of display in matrix arrangements screen picture wherein, it comprises:

Cursor position changes unit, its be configured to the direction of operation response and amplitude change described cursor will the position of display;

Described multiple selection is arranged with juxtaposition relationship in the first arranged direction associated with the first direction of operating of described operation and the second arranged direction associated with the second direction of operating of described operation;

Along the second arranged direction each selection between layout distance be shorter than along the first arranged direction between each selection layout distance;

Described cursor will display and when performing the operation of assigned operation amount on the second direction of operating in the second arranged direction the amount of exercise of the position of movement be less than described cursor will show and when performing the operation of assigned operation amount on the first direction of operating in the first arranged direction the amount of exercise of the position of movement.

2. cursor location control device according to claim 1, wherein the first arranged direction is the horizontal direction on described image display display unit thereon; And

Second arranged direction is the vertical direction on described display unit.

3. cursor location control device according to claim 1 and 2, wherein

The position allowing described cursor to move to is limited to the region of the part occupying described screen picture.

4. cursor location control device according to claim 3, wherein

Described choice arrangement is in the end in described region.

5. cursor location control device according to any one of claim 1 to 4, wherein

Described operation is the operation for rotating the input device comprising gyro sensor;

Described multiple selection is arranged with juxtaposition relationship in the first arranged direction associated with the first sense of rotation of the described operation for rotating and the second arranged direction associated with the second sense of rotation of the described operation for rotating; And

Described cursor will display and when perform in a second rotational direction specify the operation of rotation amount time in the second arranged direction the amount of exercise of the position of movement be less than described cursor will display and when performing the operation of appointment rotation amount in a first rotational direction in the first arranged direction the amount of exercise of the position of movement.

6. cursor location control device according to any one of claim 1 to 5, wherein

Quantity along the selection of the second arranged direction layout is less than the quantity of the selection of arranging along the first arranged direction.

7. for a cursor position control method for cursor location control device, for control for from multiple selection to select the cursor of in described multiple selection will the position of display in matrix arrangements screen picture wherein, described method comprises:

The direction of operation response and amplitude change described cursor by the step of the position of display;

Along the second arranged direction selection between layout distance be shorter than along the first arranged direction between selection layout distance;

8. the program performed by computing machine, described computing machine controls to be used for from multiple selection to select the cursor of described multiple selection will the position of display in matrix arrangements screen picture wherein, and described program causes described computing machine to perform:

The direction of operation response and amplitude change described cursor by the process of the position of display;

9. one kind stores the computer-readable information storage medium of the program performed by computing machine, described computing machine controls to be used for from multiple selection to select the cursor of described multiple selection will the position of display in matrix arrangements screen picture wherein, and described program causes described computing machine to perform:

Illustrate or state (amendment according to treaty the 19th article)

Statement

Amendment in claim 1 and 7 to 9 illustrate control for from multiple selection to select the cursor of in described multiple selection will the position of display in matrix arrangements screen picture wherein.

Meanwhile, the open screen picture 3 of the document 1 quoted in international search report, described screen picture comprises icon 4 arranged crosswise region 3a, 3b and 3c wherein and icon 4 is arranged in region 3d wherein with vertical and horizontal juxtaposition relationship.Document 1 is also disclosed in control device, when the position of the pointer 2 on screen picture 3 is when the X-direction be arranged in one-dimensionally wherein highlights in the 3a of region multiple icon 4 in the X direction, the direction of the motion of the pointer 2 on screen picture 3 is compared to the side (list of references 1, [0101], [0106] and Figure 17 (c)) of direction of operating in X-direction.

But, invention in the claim 1 and 7 to 9 of the application control in fact for from multiple selection to select the cursor of in described multiple selection will the position of display in matrix arrangements screen picture wherein, and the multiple icon 4 of the execution being obviously different from the invention in similar document 1 in condition precedent in the X direction the X-direction be arranged in one-dimensionally wherein highlight the control of the position of the pointer 2 in the 3a of region.

So obvious document 1 is unexposed about controlling to be used for from multiple selection to select the cursor of described multiple selection by any content of the position of display in matrix arrangements screen picture wherein.

The document 2 quoted in international search report also unexposed about control for from multiple selection to select the cursor of in described multiple selection by any content of the position of display in matrix arrangements screen picture wherein.

Claims

1. one kind for controlling the cursor location control device of the position of the cursor in image, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, and it comprises:

Operational ton data capture unit, it is configured to obtain the operational ton data with the operational ton vector association representing direction and the amplitude operated;

Operational ton component designating unit, it is configured on the basis of operational ton data, specifies the amplitude of the amplitude of the first operational ton component of the component as the operational ton vector on the first direction of operating and the second operational ton component as the component of the operational ton vector be different from the second direction of operating of the first direction of operating;

Amount of exercise component determination unit, it is configured to the amplitude of the first amount of exercise component of the component of the momental amount of exercise vector determined on the basis of the amplitude of the first operational ton component as the described cursor in expression first arranged direction, and on the basis of the amplitude of the second operational ton component, determine the amplitude of the second amount of exercise component of the component as the amount of exercise vector in the second arranged direction; And

Cursor position changes unit, its be configured to by the position of described cursor from the current location of described cursor change into interval first amount of exercise component on the first arranged direction amplitude and in the second arranged direction the position of the amplitude of interval second amount of exercise component;

Along the second arranged direction each selection group between layout distance be shorter than along the first arranged direction between each selection group layout distance;

The ratio of the amplitude of the second amount of exercise component and the amplitude of the second operational ton component is less than the ratio of the amplitude of the first amount of exercise component and the amplitude of the first operational ton component.

Second arranged direction is the vertical direction on described display unit.

3. cursor location control device according to claim 1 and 2, wherein

The position of the described cursor in described image is limited to the region of the part occupying described image.

4. cursor location control device according to claim 3, wherein

Described choice arrangement is in the end in described region.

5. cursor location control device according to any one of claim 1 to 4, wherein

Described operational ton data capture unit obtains the operational ton data with the rotation amount vector association detected by gyro sensor;

Described operational ton component designating unit, on the basis of operational ton data, specifies the amplitude of the amplitude of the first rotation amount component of the component as the operational ton vector in the first sense of rotation and the second rotation amount component as the component of the operational ton vector be different from the second sense of rotation of the first sense of rotation; And

Described amount of exercise component determination unit determines the amplitude of the first amount of exercise component on the basis of the amplitude of the first rotation amount component, and on the basis of the amplitude of the second rotation amount component, determine the amplitude of the second amount of exercise component.

6. cursor location control device according to any one of claim 1 to 5, wherein

7. one kind for controlling the cursor position control method of the position of the cursor in image, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, and described method comprises:

Operational ton data acquisition step, it obtains the operational ton data with the operational ton vector association representing direction and the amplitude operated;

Operational ton component given step, it is on the basis of operational ton data, specifies the amplitude of the amplitude of the first operational ton component of the component as the operational ton vector on the first direction of operating and the second operational ton component as the component of the operational ton vector be different from the second direction of operating of the first direction of operating;

Amount of exercise component determining step, it determines the amplitude of the first amount of exercise component of the component of the momental amount of exercise vector as the described cursor in expression first arranged direction on the basis of the amplitude of the first operational ton component, and on the basis of the amplitude of the second operational ton component, determine the amplitude of the second amount of exercise component of the component as the amount of exercise vector in the second arranged direction; And

Cursor position changes step, its by the position of described cursor from the current location of described cursor change into interval first amount of exercise component on the first arranged direction amplitude and in the second arranged direction the position of the amplitude of interval second amount of exercise component;

Along the second arranged direction selection group between layout distance be shorter than along the first arranged direction between selection layout distance;

8. the program performed by computing machine, described computer controlled imaged in the position of cursor, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, and described program causes described computing machine to perform:

For obtaining the process with the operational ton data of the operational ton vector association in the direction and amplitude that represent operation;

The process of the amplitude of the first operational ton component of the component as the operational ton vector on the first direction of operating and the amplitude as the second operational ton component of the component of the operational ton vector be different from the second direction of operating of the first direction of operating is specified on the basis in operational ton data;

On the basis of the amplitude at the first operational ton component, determine the amplitude of the first amount of exercise component of the component of the momental amount of exercise vector as the described cursor in expression first arranged direction and on the basis of the amplitude of the second operational ton component, determine the process of the amplitude of the second amount of exercise component of the component as the amount of exercise vector in the second arranged direction; And

For by the position of described cursor from the current location of described cursor change into interval first amount of exercise component on the first arranged direction amplitude and in the second arranged direction the process of the position of the amplitude of interval second amount of exercise component;

9. one kind stores the computer-readable information storage medium of the program performed by computing machine, described computer controlled imaged in the position of cursor, each multiple selection groups comprising multiple selections of arranging along the first arranged direction are expressed and are arranged along the second arranged direction being different from the first arranged direction in described image, and described program causes described computing machine to perform: